Abstract :
The excitation and detection of leaky Rayleigh waves (LRW) on fluid-solid planar and cylindrical interfaces by pulsed Gaussian transducers is modeled efficiently using a frequency-domain spectral analysis combined with the complex-transducer-point (CTP) method, uniform asymptotic techniques, and a Fourier transformation. The reflected signal from the interface, due to an incident beam phase-matched to the LRW, is given in terms of wave arrivals that are directly related to the observed phenomena, namely, a specularly reflected wave and a LRW. Numerical results, for two-dimensional transducers interacting with water-aluminum interfaces, are shown to illustrate the application of the theory. Effects due to the receiver finiteness and alignment on the detected data can be easily investigated with this formalism, and are shown here for frequency-domain data
Keywords :
Rayleigh waves; acoustic pulses; acoustic wave reflection; frequency-domain analysis; interface phenomena; spectral analysis; ultrasonic transducers; Fourier transformation; H2O-Al; Rayleigh wave detection; complex-transducer-point method; cylindrical interfaces; frequency-domain spectral analysis; incident beam phase-matching; interface reflected signal; leaky Rayleigh waves; numerical results; planar interfaces; pulsed Gaussian transducers; pulsed beam excitation; receiver finiteness; shaped fluid-solid interfaces; specularly reflected wave; two-dimensional transducers; uniform asymptotic techniques; water-Al interfaces; wave arrivals; Acoustic beams; Acoustic detectors; Acoustic pulses; Acoustic reflection; Frequency domain analysis; Leaky waves; Spectral analysis; Surface acoustic waves;
